JP3298811B2 - Data communication wireless line selection method - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for selecting a radio channel for data communication, which is used in the field of radio data communication for wirelessly transmitting a digital communication signal created by a data terminal device.

[0002]

2. Description of the Related Art FIG. 9 shows a configuration example of a conventional wireless data communication system. Referring to FIG. 9, the radio base station includes a plurality of antennas, a switch circuit, a reception electric field measurement circuit, a radio circuit, a network interface circuit, an antenna control circuit, an antenna information storage circuit, and a line control circuit. It is connected.

[0003] A wireless slave station is composed of a plurality of antennas, a switch circuit, a received electric field measuring circuit, a wireless circuit, an interface circuit, an antenna control circuit, an antenna information storage circuit, and a line control circuit, and is connected to a terminal device. I have.
FIG. 9 shows only one wireless slave station, but there are a plurality of wireless slave stations. In the wireless transmission path between the wireless base station and the wireless slave station, since the propagation path of the radio wave is not constant, the directivities of the radio waves on the various propagation paths have been shifted from each other so that signals can be transmitted. A plurality of antennas are provided for each of the wireless base station and the wireless slave station.

In the system shown in FIG. 9, an optimum one of a plurality of antennas is selected and used by a switch circuit. The radio base station may have a plurality of antennas and the radio slave station may have one antenna, or the radio base station may have one antenna and the radio slave station may have a plurality of antennas. In this type of system, a radio signal having a predetermined frame configuration is transmitted between a radio base station and a radio slave station. FIG. 10 shows an example of the frame configuration of this radio signal.

Referring to FIG. 10, each frame of the radio signal includes a reception electric field measuring signal M and request signals Rα and Rα.
β, Rγ, Rδ, Rε, the enable signal G, and the data signal D
And an acknowledgment signal A. The reception electric field measurement signal M includes information on the antenna number currently used by the radio base station. The request signals Rα, Rβ, Rγ, Rδ, and Rε are used exclusively by each of the plurality of wireless slave stations, and are used by the wireless slave stations to make a communication start request to the wireless base station. .

[0006] The permission signal G is used by the radio base station to allocate a data signal to a radio slave station. The data signal D is used for data transmission. The acknowledgment signal A is used to notify whether or not the data signal can be received. In a conventional wireless data communication device, control is performed as follows in order to detect deterioration of radio wave propagation conditions and select a radio wave propagation path having good propagation conditions.

[0007] In each frame of the radio signal, a received electric field measuring signal having information on the antenna in use is added. The wireless base station and the wireless slave station mutually observe the communication state of the received electric field measurement signal while switching the antennas. The observation result is exchanged between the radio base station and the radio slave station, and the obtained information is accumulated in each device. From the stored information, the wireless base station or the wireless slave station determines an optimal combination of antennas for communication, and instructs the other party to switch antennas. This allows
Communication quality of the wireless line is ensured.

When one of the devices detects the deterioration of the line, it searches for a combination having a good communication state from among combinations of antennas that can be communicated, which are detected and stored in advance, and the search is performed. By exchanging the results with each other, the communication antenna is reselected and the switching operation is performed.

Further, as shown in FIG. 10, request signals Rα, Rβ, Rγ, Rδ and Rε for determining whether or not to start communication are provided to each of a plurality of wireless slave stations at different times from each other, as shown in FIG. Fixedly assigned.

[0010]

In the prior art, it is necessary to investigate the propagation state at any time, even during communication, in order to grasp the state of the radio propagation path that fluctuates as needed. Therefore, the reception electric field measurement signal M
Must be constantly transmitted by either the wireless base station or the wireless slave station. This hinders improvement in data transmission efficiency.

[0011] Further, since the receiving operation is performed and the measurement is performed for all the combinations of the antennas, it is inevitable that a delay occurs when selecting the antenna.
That is, when all the measurement results are obtained, the measurement results do not match the latest state of the wireless channel due to the aging of the wireless channel, so that an optimal antenna cannot be selected. Further, even if the wireless propagation path changes from a communication disabled state to a communication enabled state, communication cannot be started immediately.

Further, since the timings of the request signals Rα, Rβ, Rγ, Rδ and Rε for determining whether or not to start communication need to be determined in advance for each wireless station, the configuration and length of the wireless signal frame must be determined. Unless is changed, the number of wireless slave stations cannot be increased. Further, since the same time zone in a wireless signal frame cannot be shared by a plurality of wireless slave stations, the time usage rate of the wireless signal frame cannot be improved. Therefore, there is a problem that the time usage rate of the radio signal frame decreases as the number of terminals increases.

An object of the present invention is to improve a reduction in data transmission efficiency due to addition of a special signal for grasping a state of a radio propagation path, and to improve the data transmission efficiency after the radio propagation path becomes communicable. One object is to reduce the time delay until communication starts, and one object is to improve the time usage rate of radio signal frames.

[0014]

[0015]

[0016]

[0017]

[0018]

[0019]

[0020]

[0021]

[0022]

Means for Solving the Problems] claim 1, a radio personal station comprising a radio base station having a first antenna means, the second antenna means capable of switching the directivity, the radio base station And a radio wave propagation path through which a radio wave propagates between the radio slave station and the radio station, the radio wave propagation path has a multipath environment that causes a change in the radio wave propagation path, and is temporally separated from each other. Performing communication using a wireless signal frame composed of a plurality of bursts, in the data communication wireless line selection method of the wireless data communication system, the length of the wireless signal frame is fixed, the first burst of the wireless signal frame, A broadcast burst including the identification information of the radio base station is allocated, the radio base station transmits the broadcast burst at regular intervals in time, and the radio slave station uses the second broadcast signal used by its own station. While sequentially switching the directivity of Na means attempts to receive the broadcast burst from the radio base station,
When the wireless slave station successfully receives the broadcast burst from the wireless base station, the wireless slave station recognizes that the wireless propagation path between the wireless base station and the wireless slave station at that time is usable, and the wireless slave station transmits the broadcast. Based on the timing at which the burst has been successfully received, communication between the wireless base station and the wireless slave station is started, and the directivity of the second antenna means in this communication is determined by the wireless slave station when the broadcast burst is received. The determination is made based on the directivity of the second antenna means detected when successful.

Since the propagation path of the radio wave between the radio base station and the radio slave station changes, the second radio slave station is set so that communication is always possible or the quality of the communication line is improved. Of the antenna means can be switched. Therefore, it is necessary to control the directivity of the second antenna means so that communication can be performed according to a change in the propagation path of the radio wave between the radio base station and the radio slave station.

According to the first aspect , a broadcast burst arranged at the head of a wireless signal frame having a fixed length is repeatedly transmitted from the wireless base station at fixed time intervals. Since the wireless slave station attempts to receive a broadcast burst from the wireless base station while sequentially switching the directivity of the second antenna means used by the own station, the wireless slave station exists within the predetermined service area of the wireless base station. In the wireless slave station to perform, within a predetermined time To,
The broadcast burst can be received at least once. For example, if the number of selectable directivities is Na and the length of the radio signal frame is Tf, the time To is represented by the product of Na and Tf.

Since the broadcast burst contains the identification information of the wireless base station, the wireless slave station can recognize from the broadcast burst whether or not this signal is from the intended communication partner. . When the wireless slave station has successfully received the broadcast burst, between the wireless base station and the wireless slave station,
A wireless channel is available. That is, if the directivity is close to the directivity of the second antenna means of the wireless slave station at that time, communication between the wireless slave station and the wireless base station is performed unless a large change occurs in the wireless propagation path. It is possible.

When the communication state of the wireless base station changes periodically at each time To, communication can be performed immediately after the wireless slave station successfully receives the broadcast burst or after a time To. The directivity of the second antenna means during communication is detected when a broadcast burst is received.
The direction may be the same as or the direction adjacent to it.

A second aspect of the present invention is a first aspect in which the directivity can be switched.
A radio base station including an antenna unit, a radio slave station including a second antenna unit capable of switching directivity,
The radio base station is configured by a radio wave propagation path through which a radio wave propagates between the radio base station and the radio slave station, and the radio wave propagation path has a multipath environment that causes a change in a radio wave propagation path. A method for selecting a data communication radio channel of a radio data communication system, in which communication is performed using a radio signal frame composed of a plurality of bursts separated from each other, wherein the length of the radio signal frame is fixed, The broadcast burst including the identification information of the wireless base station is allocated to the burst, and the wireless base station transmits the broadcast burst while sequentially switching the directivity of the first antenna means at regular time intervals. While the wireless slave station attempts to receive a broadcast burst from the wireless base station while sequentially switching the directivity of the second antenna means, If the broadcast burst is successfully received from the wireless base station, the wireless communication station recognizes that the wireless propagation path between the wireless base station and the wireless slave station at that time is usable, and the wireless slave station succeeds in receiving the broadcast burst. The communication between the radio base station and the radio slave station is started based on the obtained timing, and the radio slave station determines the directivity of the first antenna means and the second antenna means in this communication by the broadcast burst. Is determined based on the directivities of the first antenna means and the second antenna means detected when the reception of the first antenna is successful.

Since the propagation path of the radio wave between the radio base station and the radio slave station changes, the first radio base station must be designed so that communication is always possible or the quality of the communication line is improved. And the directivity of the second antenna means of the wireless slave station can be switched. Therefore, it is necessary to control the directivity of the first and second antenna means so that communication is possible in accordance with a change in the propagation path of the radio wave between the radio base station and the radio slave station. .

According to the second aspect , the broadcast burst arranged at the head of the wireless signal frame having a fixed length is repeatedly transmitted from the wireless base station at a fixed time interval. The directivity of the first antenna means is sequentially switched in a predetermined order. The directivity can be switched by switching a plurality of antennas, mechanically rotating the antenna, switching the characteristics of the electrical antenna, and the like.

[0030] Therefore, a radio slave station existing within a predetermined service area of the radio base station can receive the broadcast burst at least once within a predetermined time To. For example, if the number of selectable directivities of the first antenna means is Na and the length of the radio signal frame is Tf, the time To is represented by the product of Na and Tf. Since the wireless slave station attempts to receive a broadcast burst from the wireless base station while sequentially switching the directivity of the second antenna means used by the wireless station, the wireless slave station is located within the service area of the wireless base station. If it is located, the wireless slave station receives the broadcast burst within a predetermined time.

Since the broadcast burst contains the identification information of the radio base station, the radio slave station can recognize whether or not the signal is from the intended communication partner by the broadcast burst. . When the wireless slave station has successfully received the broadcast burst, between the wireless base station and the wireless slave station,
A wireless channel is available. In other words, if the directivity of the first antenna means and the directivity of the second antenna means are close to the respective directivities when the broadcast signal is received, the radio elements are not changed unless a large change occurs in the radio propagation path. Communication is possible between the station and the radio base station.

Since the directivity of the first antenna means is sequentially switched, a communicable state periodically occurs at each time To. Therefore, for example, communication can be performed immediately after the wireless slave station successfully receives the broadcast burst or after a time To. The first when communicating
And the directivity of the second antenna means is the same as each directivity detected when the broadcast burst is received,
Alternatively, it may be in a direction adjacent to it.

The third aspect, in the data communication radio channel selection method of claim 2, wherein, at the beginning of the burst of the radio signal frame, includes information about the state of the radio base station, the radio personal station, from the radio base station By entering the communication start procedure triggered by the completion of the reception of the broadcast burst, the communication availability notification to a plurality of wireless slave stations and the plurality of wireless slave stations entering the communication start procedure are temporally dispersed. I do.

When there are a large number of wireless slave stations, these wireless slave stations are usually located in various directions with respect to the wireless base station. Therefore, when a wireless base station transmits a wireless signal using a directional antenna, the number of wireless slave stations at a position at which a broadcast burst can be received at a certain time is limited. Therefore, if the wireless slave station controls to enter the communication start procedure triggered by the completion of the reception of the broadcast burst from the wireless base station, according to the distribution state of the location of the wireless slave station,
The wireless slave stations receiving the communication availability notification and the wireless slave stations entering the communication start procedure are temporally dispersed.

By including information on the state of the radio base station, for example, the number of antennas and the frame period of the radio signal, in the first burst of the radio signal frame, each radio slave station can predict the communicable timing in advance. You.

[0036]

[0037]

[0038] Claim 4 relates to a radio base station including a first antenna unit, a radio slave station including a second antenna unit capable of switching directivity, and a radio base station between the radio base station and the radio slave station. A fixed length constituted by a plurality of bursts separated from each other in time, wherein the fixed length is constituted by a radio wave propagation path through which a radio wave propagates, the radio wave propagation path has a multipath environment in which a propagation path of the radio wave is changed. In the data communication wireless channel selection method of the wireless data communication system, which performs communication using the wireless signal frame, the wireless slave station attempts to receive a broadcast signal transmitted from the wireless base station at regular intervals, and When the broadcast signal is successfully received, synchronization is established at a timing based on the broadcast signal, and when the wireless slave station successfully receives the broadcast signal, the radio slave station receives the broadcast signal. To record information on orientation of the second antenna means of the own station, the radio personal station,
When the broadcast signal is successfully received, the directivity of the second antenna means is controlled to be the same as the directivity of the second antenna means of the own station when the broadcast signal is received, and a communication start request is issued. A signal is transmitted to the wireless base station, and the wireless slave station controls the directivity of the second antenna means in the same manner as the directivity of the second antenna means of the own station when transmitting the communication start request signal. Then, the wireless slave station waits for the permission signal, and, when receiving the permission signal addressed to the own station, transmits the data in the predetermined data signal, thereby receiving the communication channel from the wireless base station. And a communication start request is made.

The wireless slave station controls as follows. It repeatedly tries to receive a broadcast signal transmitted from the wireless base station at regular intervals. Then, when the notification signal is successfully received, synchronization is established at a timing based on the notification signal. Further, when the broadcast signal is successfully received, the wireless slave station records information on the directivity of the second antenna unit of the wireless station when the broadcast signal is received.

Further, when the radio slave station has successfully received the broadcast signal, the radio slave station has the same second antenna means as the directivity of the second antenna means at the time of receiving the broadcast signal. And transmits a communication start request signal to the wireless base station. Next, the wireless slave station controls the directivity of the second antenna means in the same manner as the directivity of the second antenna means of the own station when transmitting the communication start request signal, and waits for the permission signal. . Then, when the permission signal addressed to the own station is received, data transmission is performed using a predetermined data signal.

According to this, a communication start request can be made without receiving a communication channel assignment from the radio base station. Also, without exchanging information on the combination of the directivity of the available antenna means between the radio base station and the radio slave station, the unilateral determination of the propagation path state and the start of communication can be performed by the radio slave station. Data communication becomes possible by the timing judgment.

According to a fifth aspect of the present invention, in the data communication wireless channel selecting method according to the fourth aspect , a communication start request signal area is allocated in advance to a plurality of bursts in the wireless signal frame, and the wireless slave station generates a random number. Then, a communication start request signal is transmitted for a burst at a timing according to the obtained random number. If there are many wireless slave stations,
The probability of a plurality of wireless slave stations simultaneously generating a communication start request increases, and the collision of a plurality of communication start request signals often results in failure of communication channel assignment.

According to the fifth aspect , the area of the communication start request signal is allocated in advance to a plurality of bursts in the radio signal frame. Then, the wireless slave station generates a random number, and transmits a communication start request signal to a burst at a timing corresponding to the obtained random number. As a result, a plurality of communication start request signals are temporally dispersed into a plurality of bursts.
Signal collisions are avoided. Therefore, the number of wireless slave stations can be increased.

[0044]

DESCRIPTION OF THE PREFERRED EMBODIMENTS (First Embodiment) FIGS. 1, 2, 3, 4, 5, and 6 show the configuration and operation of a system according to this embodiment. This form is claimed in claim 1, claim 2,
This corresponds to claims 3 and 4 .

FIG. 1 is a block diagram showing a configuration example of the radio base station 1, and FIG. 2 is a block diagram showing a configuration example of the radio slave station 2. FIG. 3 is a time chart showing a frame configuration of a radio signal used for communication between the radio base station 1 of FIG. 1 and the radio slave station 2 of FIG.

FIG. 4 is a time chart showing an example of starting communication between the wireless base station 1 in FIG. 1 and the wireless slave station 2 in FIG. FIG. 5 is a flowchart illustrating communication start control of the wireless slave station 2. FIG. 6 is a flowchart showing communication start control of the wireless base station 1. In this embodiment, the first antenna means of claim 1, claim 2, and claim 4 is:
The second antenna means is embodied as the antenna group 25 in FIG. 2 and embodied as the antenna group 15 in FIG.

First, the radio base station 1 will be described with reference to FIG. In this example, the radio base station 1 includes a radio transmission / reception circuit 11, an antenna switching circuit 12, a line control circuit 1
3, a network interface circuit 14 and an antenna group 15. A wired backbone network 16 is connected to the wireless base station 1. In order to divide the service area (communication area) covered by the wireless base station 1 into a plurality of areas according to directions, in this example, the antenna group 15
, Twelve sector antennas (fan-shaped antennas) having directivity are installed with their directions shifted from each other.

In other words, by switching and using the 12 sector antennas, the direction of the communication area can be switched. Even when the state of the radio wave propagation path between the wireless base station and the wireless slave station changes or when the wireless slave station moves, the quality of the wireless communication line can be maintained by switching the directivity of the antenna. . Note that, instead of the antenna group 15 that selectively uses a large number of antennas, an antenna configured to mechanically rotate the direction of the antenna or to electrically switch the directivity may be provided.

One sector antenna included in the antenna group 15 is selectively switched by the antenna switching circuit 12.
Connected to the wireless transmission / reception circuit 11. The wireless transmission / reception circuit 11 is connected to a wired backbone network 16 via a network interface circuit 14.

That is, the wireless base station 1 allows the wired backbone network 16 to be connected to a wireless line. The wireless transmission / reception circuit 11, the antenna switching circuit 12, and the network interface circuit 14 are controlled by a line control circuit 13. The line control circuit 13 includes a control computer. Next, the wireless slave station 2 will be described with reference to FIG. In this example, the wireless slave station 2 includes a wireless transmission / reception circuit 21, an antenna switching circuit 22, a line control circuit 23, an input / output interface circuit 24, an antenna group 2
5, a transmission / reception timing control circuit 26 and an available antenna management table 27. A terminal device 28 is connected to the wireless slave station 2.

In this example, ten sector antennas having directivity are installed in the antenna group 25 with their directions shifted from each other to improve the quality of the communication line.
That is, by switching and using the ten sector antennas, the directivity of the antenna can be directed to the direction of the wireless base station to be communicated. Further, even when the state of the radio wave propagation path between the radio base station and the radio slave station changes, the quality of the radio communication line can be maintained by switching the directivity of the antenna.

Note that, instead of the antenna group 25 that selectively uses a large number of antennas, an antenna having a configuration in which the direction of the antenna is mechanically rotated or the directivity is electrically switched may be provided. One sector antenna included in the antenna group 25 is selectively connected to the wireless transmission / reception circuit 21 by the antenna switching circuit 22. The wireless transmission / reception circuit 21 is connected to a terminal device 28 via an input / output interface circuit 24.

That is, the terminal device 28 can be connected to a wireless line by the wireless slave station 2. The transmission / reception timing control circuit 26 performs transmission / reception control based on relative time management based on the head of the wireless signal frame and assembles the wireless signal frame. The usable antenna management table 27 holds information on the number (position) of the sector antenna of the antenna group 25 selected when the broadcast signal transmitted from the wireless base station is received.

The line control circuit 23 includes the radio transmission / reception circuit 2
1, the input / output interface circuit 24 and the transmission / reception timing control circuit 26 are controlled. The line control circuit 23 includes a control computer. FIG. 3 shows a frame configuration example of a radio signal used for communication between the radio base station 1 and the radio slave station 2.

In this example, as shown in FIG. 3, each frame of the radio signal is composed of a broadcast signal B1, a request signal B2, a permission signal B3, a data signal B4, and a reception confirmation signal B5. Notification signal B1, request signal B2, permission signal B
3. Each of the data signal B4 and the reception confirmation signal B5 is one burst, that is, a continuous signal. Notification signal B1, request signal B2, permission signal B3, data signal B4
Each burst of the acknowledgment signal B5 has a synchronization signal section B11, an identification signal section B12, and an information section B13. The burst signal can be synchronized with the signal of the synchronization signal section B11.

Notification signal B1, request signal B2, permission signal B
3. The data signal B4 and the acknowledgment signal B5 are respectively defined as follows. The notification signal B1 is transmitted from the wireless base station 1 to the wireless slave station 2. The broadcast signal B1 is a signal that can be received by all the wireless slave stations 2 and
Have information about Specifically, the broadcast signal B includes the identification information of the wireless base station 1, the number of antennas of the antenna group 15 (the number of selectable directivities), the frame period of the wireless signal, and the like.
1 included.

The request signal B2 is transmitted from the wireless slave station 2 to the wireless base station 1, and has information on a communication start request from the wireless slave station 2. The permission signal B3 is transmitted from the wireless base station 1 to the wireless slave station 2, and includes information such as availability of the data signal B4 following the permission signal B3, assignment of a wireless burst, control instruction of the wireless slave station 2, and the like. Contains information.

The data signal B4 is a signal transmitted bidirectionally between the radio base station 1 and the radio slave station 2, and includes the content of data to be transmitted. The acknowledgment signal B5 is bidirectionally transmitted between the wireless base station 1 and the wireless slave station 2, and has information on the result of receiving the data signal B4. What is characteristic here is that one burst of the broadcast signal B1 is arranged in the first burst of each frame of the radio signal. Also, it is characteristic that the request signal B2 is arranged at a time delayed by a certain time from the notification signal B1. Note that, in this example, the request signal B2 is set to 1 in one frame.
Although only bursts are provided, a request signal may be composed of a plurality of bursts.

Next, the contents of the communication start control in the radio base station 1 will be described with reference to FIG. This control is executed by the line control circuit 13. In the communication start control, the notification signal B1 is transmitted in the first step S11. The antenna used at this time is antenna group 1
The value is determined by the contents of the counter N from among the 12 sector antennas that make up 5.

The content of the counter N is sequentially updated for each frame of the radio signal, and takes a value in the range of 1 to 12. That is, when the value of the counter N is 1, 2, 3, 4,..., Respectively, the first, second, third, fourth,.
The sector antenna is selected. After transmitting the notification signal, the wireless base station 1 attempts to receive the request signal B2 from the wireless slave station 2 in the next step S12. At this time, the antenna used by the wireless base station 1 is the same as that in step S11. That is, an attempt is made to receive the request signal B2 using the same antenna as that used for transmitting the notification signal B1.

In step S12, if the wireless base station 1 has been able to receive the request signal B2 from the wireless slave station 2, then in step S13, the data is sent to the wireless slave station 2 that transmitted the request signal B2. The signal B4 is assigned. That is, the assignment is made so that the wireless child station 2 can use the data signal B4. If the request signal B2 cannot be received in step S12, a data signal B4 to be used for communication from the wireless base station 1 or communication from the previously requested wireless slave station 2 is allocated.

After the assignment is determined, the radio base station 1
In step S15, the permission signal B3 including the information on the assignment of the data signal B4 is transmitted. At this time, the antenna used by the wireless base station 1 is the same as that in step S11. That is, the permission signal B3 is transmitted using the same antenna as that used for transmitting the notification signal B1. Next step S1
At 6, the wireless base station 1 transmits or receives the data signal B4. Further, in the following step S17, the reception confirmation signal B
5 is received or transmitted, and data delivery confirmation is performed.

Under the control of steps S11 to S17, one frame of the radio signal is processed. Finally, in step S18, the content of the counter N is updated. However,
When the updated value of the counter N exceeds the maximum value Nmax (12), the process proceeds from step S19 to S20, and the counter N is initialized to 1. Thereafter, the process returns to step S11, and shifts to processing of the next frame.

Next, with reference to FIG. 5, the contents of the communication start control in the wireless slave station 2 will be described. This control is executed by the line control circuit 23. When the wireless slave station 2 attempts to start communication, the wireless slave station 2 performs the first step S1.
Then, an attempt is made to receive the notification signal B1. When executing step B1, any one of the ten sector antennas constituting the antenna group 25 is selected.

Here, while the notification signal B1 cannot be received,
It recognizes that there is no communicable wireless channel between the wireless slave station 2 and the wireless base station 1. Then, step S1
Is repeated to further attempt to receive the notification signal B1. If the notification signal B1 cannot be received even after the elapse of one frame period Tf of the wireless signal, the process proceeds to step S10 via step S6. In step S10, the antenna to be used is switched. Therefore, when the notification signal B1 cannot be received, the antenna used by the wireless slave station 2 is sequentially switched in step S10 for each frame period Tf.

When the notification signal B1 can be received, the wireless slave station 2 recognizes that an effective radio wave propagation path exists between the wireless slave station 2 and the wireless base station 1 under the communication conditions at that moment. In addition, by receiving the notification signal B1, it is recognized that permission to enter the communication start request procedure has been assigned from the wireless base station 1. In the next step S2, the wireless slave station 2
The number of the own station's sector antenna used at the time of receiving the broadcast signal B1 is stored in the available antenna management table 27.
To record.

The wireless slave station 2 entered the communication start request procedure
Is a request signal B2 following the notification signal B1 in step S3.
Is used to send a communication start request to the wireless base station 1. However, since there are a large number of wireless slave stations 2, the timing of the request signal B2 included in each frame of the wireless signal is shared and used by a plurality of wireless slave stations 2. That is, a plurality of wireless slave stations 2 may transmit the request signal B2 at the same time.

Therefore, the request signal B transmitted by the wireless slave station 2
2 is not guaranteed to be received by the wireless base station 1, and the wireless slave station 2 cannot confirm that the wireless base station 1 has received its own request signal B2. Therefore, after transmitting the request signal B2 for starting communication, the wireless
In step 4, the next permission signal B3 is awaited using the same antenna used when the request signal B2 was transmitted.

When receiving the permission signal B3 for the own station in step S4, the wireless slave station 2 regards that a response regarding the assignment of the data signal to the own station has been made, and
The delivery of the request signal B2 transmitted in step S3 to the wireless base station 1 is confirmed. If the wireless slave station 2 cannot receive the permission signal B3 for its own station in step S4, it recognizes that the delivery of the request signal B2 transmitted in step S3 has failed, and starts the retransmission procedure. That is, the process returns to step S1, and waits for the notification signal B1 of the next frame.

When the permission signal B3 is received in step S4, the wireless slave station 2 analyzes the contents of the permission signal B3 in step S7. When confirming that the data signal B4 has been allocated from the wireless base station 1 by the permission signal B3, the wireless slave station 2 transmits the specified data signal B4.
At timing 4, data is transmitted as a data signal B4.

When the assignment of reception for the data signal B4 is recognized by the permission signal B3, the wireless slave station 2
Is the data signal B from the wireless base station 1 in step S7.
4 is received. In step S7, the data signal B4
Is transmitted in step S8, and when the reception confirmation signal B5 is received, the wireless slave station 2 confirms the delivery of the data signal B4 to the radio base station 1, The communication start control ends. If the reception confirmation signal B5 cannot be received, the radio base station 1 of the data signal B4
Recognizes that delivery to the server has failed, and proceeds to step S9.
Initiate the retransmission procedure.

In step S7, when receiving the data signal B4, the wireless slave station 2 that has tried to receive the data signal B4 transmits a reception confirmation signal B5 to the wireless base station 1, and ends the communication start procedure. I do. If the data signal B4 is not received, the acknowledgment signal B5 is not transmitted, and step S8 is performed.
Then, the process proceeds to S9 to start the retransmission procedure. Wireless base station 1
A specific example of the communication start control operation between the wireless slave station 2 and
This will be described with reference to FIG.

The broadcast signal B1 is always transmitted from the radio base station 1 to the radio slave station 2 as the first burst of the five bursts constituting each frame of the radio signal. Also,
The antenna used by the wireless base station 1 is sequentially switched for each frame of the wireless signal. That is, the notification signal B1 is
The data is sequentially transmitted from the wireless base station 1 to each direction in the service area.

Therefore, the frame period of the radio signal is Tf,
When the number of antennas of the wireless base station 1 is Na, the wireless slave station 2 located in a place capable of communicating with the wireless base station 1 has at least one antenna for a predetermined time To corresponding to the product of Tf and Na.
Notification signal B transmitted through a communicable path more than once
1 can be received. Therefore, the wireless slave station 2 waiting for the communication start request first tries to receive the notification signal B1. Also,
In the wireless slave station 2 having a plurality of antennas, the antenna used by the own station is sequentially switched every frame period Tf to try to receive the notification signal B1.

The wireless slave station 2 that has received the notification signal B1
When receiving the notification signal B1, the radio base station 1 and the radio slave station 2
During this time, it recognizes that a radio wave propagation path available for communication exists at that moment. The wireless slave station 2 uses the wireless slave station 2 before receiving the broadcast signal B1 before the spatial propagation path condition is not significantly changed, that is, within a relatively short time after receiving the broadcast signal B1. A communication start request is made using the same antenna as the antenna that has been used.

Since the communication start control is performed in such a manner, the combination of the antenna used for communication between both the wireless base station 1 and the wireless slave station 2 and the wireless transmission path to be used correspond to the broadcast signal in the wireless slave station 2. It is determined only by the reception state of B1. Further, since the frame period Tf of the radio signal is constant, the time T from when each radio slave station 2 first receives the notification signal B1 until the next reception of the notification signal B1 becomes possible.
o also takes a constant value. That is, when the wireless slave station 2 recognizes the total number Na of antennas used by the wireless base station 1, the wireless slave station 2 can predict the receivable timing of the notification signal B1 after the second time.

Further, since the frame of each radio signal has a fixed length, once the radio signal station 2 synchronizes the radio signal timing with the broadcast signal B 1, the radio slave station 2 can transmit the radio signal within a range where no large change occurs in the state of the transmission path. Even in an arbitrary burst several frames ahead, the signal can be used only by control by time management. In this embodiment, for simplicity of description, the case where the request signal B2 is transmitted in the same frame as that in which the broadcast signal B1 is received has been described. Then, the request signal B2 may be transmitted several frames after the reception of the notification signal B1.

In this embodiment, the wireless slave station 2 transmits the notification signal B1
The same antenna that was used when receiving the
The wireless base station 1 and the wireless slave station 2 use them to communicate the request signal B2, the permission signal B3, the data signal B4, and the reception confirmation signal B5. However, the wireless slave station 2 receives the notification signal B
1 is used by the radio base station 1 and the radio slave station 2 to communicate with the request signal B2, the permission signal B3, the data signal B4, and the reception confirmation signal B5. It is also possible.

In other words, when a plurality of directional antennas whose directions are shifted from each other are used, the antennas adjacent to each other have a directivity partially overlapped, and are used when the wireless slave station 2 receives the broadcast signal B1. In some cases, communication is possible even when an antenna having directivity adjacent to the antenna is used. Also, when the state of the wireless propagation path between the wireless base station 1 and the wireless slave station 2 changes, communication becomes possible with an antenna whose directivity is adjacent to the antenna used when the wireless slave station 2 receives the broadcast signal B1. Often.

In any case, the wireless slave station 2 transmits the notification signal B
1 is used by the radio base station 1 and the radio slave station 2 to determine an antenna determined on the basis of the directivity of the antenna used when receiving the request signal B2, the permission signal B3, the data signal B4, and the reception confirmation signal B5. It is desirable to perform communication.

In this embodiment, the radio base station 1 and the radio slave station 2
Control each antenna so as to switch the antenna every frame period Tf of the radio signal. However, for example, one of the antennas of the wireless base station 1 and the wireless slave station 2 is switched every frame period Tf, and the other antenna is switched at twice, three times, four times,. It may be controlled.

(Second Embodiment) FIG. 7 shows an example of the configuration of a wireless slave station 2B of this embodiment, and FIG. 8 shows the frame configuration of a wireless signal. The configuration and operation of the wireless base station 1 and the elements not described are the same as those of the first embodiment. This embodiment corresponds to claim 5 . Wireless slave station 2B shown in FIG.
Is different from the wireless slave station 2 of FIG. 2 in that a random number generation circuit 29 and a timing switching circuit 30 are added.

As shown in FIG. 8, in this embodiment, each frame of the radio signal is composed of seven bursts. Request signals B2, B3 and B4 are allocated to the second, third and fourth bursts in the frame. In the fifth, sixth and seventh bursts in the frame, the enable signal B5, the data signal B6 and the acknowledgment signal B
7 is assigned.

In this embodiment, the wireless slave station 2B can transmit a request for starting communication to the wireless base station 1 by using any one of the timings of the request signals B2, B3 and B4. Actually, when requesting the start of communication, the wireless slave station 2B generates a numerical value (random number) of 1, 2, or 3 by the random number generation circuit 29 for each frame of the wireless signal, It is determined which of the signals B2, B3 and B4 is used.

Therefore, even if there are a large number of wireless slave stations 2B desiring to communicate with the wireless base station 1, the request signals transmitted by the plurality of wireless slave stations 2B are included in the frame. Since the signals are temporally dispersed at the timings of the third, third, and fourth bursts, the probability of collision of a plurality of request signals is reduced. For this reason, a plurality of wireless slave stations 2
Even when B intends to communicate with the same radio base station 1, the communication start request can be processed without previously allocating bursts of radio signals to be used.

[0086]

[0087]

[0088]

[0089]

The Effect of the Invention (Claim 1) antenna directivity of the radio personal station, if it can be selected from a plurality, can easily determine the possible directivity of the appropriate antenna communication. Further, communication start control can be performed at an appropriate timing at which communication is possible. Further, the condition of the radio propagation path between the radio base station and the radio slave station and the directivity of the antenna to be used can be determined without mutually exchanging antenna information between the radio base station and the radio slave station. . Further, the communication start requests of the respective wireless slave stations can be temporally dispersed and processed without prior reservation.

(Claim 2 ) When the directivity of each antenna of the radio base station and the radio slave station can be selected from a plurality of antennas, the directivity of an appropriate antenna capable of communication can be easily determined. Further, communication start control can be performed at an appropriate timing at which communication is possible. Further, the condition of the radio propagation path between the radio base station and the radio slave station and the directivity of the antenna to be used can be determined without mutually exchanging antenna information between the radio base station and the radio slave station. . Further, the communication start requests of the respective wireless slave stations can be temporally dispersed and processed without prior reservation.

(Claim 3 ) Since the wireless slave station enters the communication start procedure triggered by the completion of the reception of the broadcast burst from the wireless base station, the wireless slave station is set in accordance with the distribution state of the location of the wireless slave station.
The wireless slave stations receiving the communication availability notification and the wireless slave stations entering the communication start procedure are temporally dispersed. Also, by including information on the state of the wireless base station, for example, the number of antennas and the frame period of the wireless signal, in the first burst of the wireless signal frame, each wireless slave station can predict the communicable timing in advance. Therefore, the notification of the availability of communication and the timing of starting the communication start procedure can be delayed longer than the frame period. This is more effective in temporally dispersing a large number of wireless slave stations communicating with the wireless base station.

[0092]

(Claim 4 ) The condition of the radio propagation path between the radio base station and the radio slave station and the antenna to be used without mutually exchanging antenna information between the radio base station and the radio slave station. Can be determined. Also, without prior reservation, the communication start request of each wireless slave station is dispersed in time,
Can be processed.

Further, upon completion of the reception of the broadcast signal, the radio slave station confirms the existence of the radio propagation path between the radio slave station and the radio base station, and recognizes the antenna to be used by the station and the communicable timing. Can be. Further, the wireless slave station can determine the timing at which the wireless station can start communication based on whether or not a notification signal can be received. (Claim 5 ) Even when a large number of wireless slave stations desiring communication with a wireless base station are present at positions close to each other, the request signals transmitted by the plurality of wireless slave stations are transmitted at different burst timings within a frame. In addition, since the signals are temporally dispersed, the probability of collision of a plurality of request signals is reduced.

Therefore, even when a plurality of wireless slave stations attempt to communicate with the same wireless base station 1, a communication start request can be processed without previously allocating bursts of wireless signals to be used.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration example of a wireless base station 1.

FIG. 2 is a block diagram illustrating a configuration of a wireless slave station 2 according to the first embodiment.

FIG. 3 is a time chart showing a frame configuration of a radio signal used for communication between the radio base station 1 of FIG. 1 and the radio slave station 2 of FIG. 2;

4 is a time chart showing an example of starting communication between the wireless base station 1 of FIG. 1 and the wireless slave station 2 of FIG. 2;

FIG. 5 is a flowchart showing communication start control of the wireless slave station 2.

FIG. 6 is a flowchart showing communication start control of the wireless base station 1.

FIG. 7 is a block diagram illustrating a configuration of a wireless slave station according to the second embodiment.

FIG. 8 is a time chart showing a frame configuration of a radio signal used in the second embodiment.

FIG. 9 is a block diagram showing a configuration of a conventional radio base station and a radio slave station.

FIG. 10 is a time chart showing a frame configuration of a wireless signal used for communication between a conventional wireless base station and a wireless slave station.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 wireless base station 2 wireless slave station 11 wireless transmission and reception circuit of wireless base station 12 antenna switching circuit of wireless base station 13 line control circuit of wireless base station 14 network interface circuit of wireless base station 15 antenna group of wireless base station 16 wired trunk Network 21 Radio transmission / reception circuit of radio slave station 22 Antenna switching circuit of radio slave station 23 Line control circuit of radio slave station 24 Input / output interface circuit of radio slave station 25 Antenna group of radio slave station 26 Transmission / reception timing control circuit of radio slave station 27 Available antenna management table for wireless slave station 28 Terminal device 29 Random number generation circuit 30 Timing switching circuit

Continuation of front page (56) References JP-A-8-331040 (JP, A) JP-A-8-125665 (JP, A) JP-A-1-106530 (JP, A) (58) Fields investigated (Int) .Cl. ⁷ , DB name) H04B ^7/ 24-7/26 113 H04Q ^7/ 00-7/38

Claims (5)

(57) [Claims] And 1. A radio base station comprising a first antenna, and the radio personal station having a second antenna means capable of switching the directivity, the radio between the radio base station and the wireless child station A radio signal frame composed of a radio wave propagation path through which a radio wave propagates, having a multipath environment in which a propagation path of a radio wave is changed in the radio wave propagation path, and configured by a plurality of bursts separated from each other in time. In the data communication radio channel selection method of a radio data communication system, the length of a radio signal frame is fixed, and a broadcast burst including identification information of a radio base station is included in a head burst of the radio signal frame. The radio base station transmits the broadcast burst at regular time intervals, and the radio slave station sequentially switches the directivity of the second antenna means used by the radio base station. While receiving the broadcast burst from the wireless base station, the wireless slave station, upon successfully receiving the broadcast burst from the wireless base station, performs wireless transmission between the wireless base station and the wireless slave station at that time. And that the wireless slave station starts communication between the wireless base station and the wireless slave station based on the timing at which the wireless slave station has successfully received the broadcast burst, and the second antenna in this communication. A method for selecting a radio channel for data communication, wherein the directivity of the means is determined based on the directivity of the second antenna means detected when the radio station succeeds in receiving the broadcast burst. 2. A radio base station comprising first antenna means capable of switching directivity, a radio slave station comprising second antenna means capable of switching directivity, and said radio base station and said radio base station. A plurality of bursts, each of which is constituted by a radio wave propagation path through which a radio wave propagates with a slave station, has a multipath environment in which the radio wave propagation path changes in the radio wave propagation path, and is temporally separated from each other. In the data communication radio channel selection method of the radio data communication system, which performs communication using a radio signal frame constituted by: a radio signal frame having a constant length, The radio base station allocates a broadcast burst including the identification information of the first antenna unit at predetermined time intervals while sequentially switching the directivity of the first antenna means. The wireless slave station attempts to receive a broadcast burst from the wireless base station while sequentially switching the directivity of the second antenna means, and the wireless slave station transmits the broadcast burst from the wireless base station. If the broadcast burst is successfully received, it is recognized that the wireless propagation path between the wireless base station and the wireless slave station at that time is usable, and based on the timing at which the wireless slave station successfully receives the broadcast burst, While starting communication between the wireless base station and the wireless slave station, the directivity of the first antenna means and the second antenna means in this communication is changed when the wireless slave station successfully receives the broadcast burst. A data communication wireless channel selection method, wherein the determination is made based on the detected directivities of the first antenna means and the second antenna means. 3. The data communication radio line selecting method according to claim 2, wherein the first burst of the radio signal frame includes:
Including information about the state of the wireless base station, the wireless slave station enters a communication start procedure triggered by the completion of reception of a broadcast burst from the wireless base station, and thereby notifies a plurality of wireless slave stations of communication availability and performs communication. A method for selecting a wireless communication line for data communication, wherein a plurality of wireless slave stations entering a start procedure are dispersed in time. 4. A radio base station having first antenna means, a radio slave station having second antenna means capable of switching directivity, and a radio base station between said radio base station and said radio slave station. A fixed length constituted by a plurality of bursts separated from each other in time, wherein the fixed length is constituted by a radio wave propagation path through which a radio wave propagates, the radio wave propagation path has a multipath environment in which a propagation path of the radio wave is changed. In the data communication wireless channel selection method of the wireless data communication system, which performs communication using the wireless signal frame, the wireless slave station attempts to receive a broadcast signal transmitted from the wireless base station at regular intervals. When the broadcast signal is successfully received, synchronization is established at a timing based on the broadcast signal, and the wireless slave station receives the broadcast signal when the broadcast signal is successfully received. The wireless slave station records the information on the directivity of the second antenna means of its own station, and, if the broadcast signal has been successfully received, the second slave means of its own station at the time of receiving the broadcast signal Controlling the directivity of the second antenna means, and transmitting a communication start request signal to the radio base station. The radio slave station transmits a communication start request signal to the radio base station when transmitting the communication start request signal. In the same manner as the directivity of the second antenna means, the directivity of the second antenna means is controlled to wait for a permission signal. By transmitting data in the data signal,
A data communication wireless channel selection method, wherein a communication start request is made without receiving a communication channel assignment from a wireless base station. 5. A data communication radio channel selecting method according to claim 4 , wherein a communication start request signal area is allocated in advance to a plurality of bursts in said radio signal frame, and a radio station generates a random number. A method for selecting a data communication wireless channel, comprising transmitting a communication start request signal for a burst at a timing according to the obtained random number.